JP2003272370A - Flexible disk drive and frame structure for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the cost of products (VE) and to reduce the weights of the products by reducing the material cost of a flexible disk drive. <P>SOLUTION: A main frame (13A) has a structure which has the dimensions to permit mounting of only the high-accuracy parts (15, 16 and 300) and from which the front surface of the frame is cut off. A lower cover (70A) covering the under surface of the main frame is provided with a function as a sub-frame to be mounted with low-accuracy parts (702, 703, 704 and 705) corresponding to the front section of the frame subjected to the cutting off. As a result, the main frame and the sub-frame of the lower cover are combined to act the function as one frame. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flexible disk drive, and more particularly to its frame structure.

[0002]

2. Description of the Related Art As is well known, a flexible disk drive (hereinafter abbreviated as "FDD") has a flexible disk (hereinafter abbreviated as "FD" or "media") inserted therein. Is a device for recording / reproducing data on / from the disc-shaped magnetic recording medium. Then, such a flexible disk drive is mounted in a laptop computer, a notebook computer, or a portable electronic device such as a notebook word processor.

A flexible disk drive of this type includes a magnetic head for reading / writing data from / to a magnetic recording medium of a flexible disk, and a movable magnetic head for the flexible disk along a predetermined radial direction. A carriage assembly supported at the tip, a stepping motor that moves the carriage assembly along the predetermined radial direction, and a DD (direct drive) motor such as a spindle motor that rotationally drives a magnetic recording medium while holding a flexible disk. have.

Various FDD control devices for controlling such a flexible disk drive have been conventionally proposed. For example, Japanese Patent Laid-Open No. 9-97493 discloses a read / write method for reading / writing the above data.
A write system (hereinafter referred to as R / W system) control circuit, a stepping motor system (hereinafter referred to as STP system) control circuit for controlling the drive of the stepping motor, and for controlling the operation of the entire flexible disk drive. And a control system (hereinafter, referred to as a CTL system) control circuit are incorporated in a one-chip IC. This one-chip IC is generally an M that integrates many MOSFETs.
It is realized by OS / IC.

The FDD control device is the one-chip IC
Besides, a spindle motor IC for controlling the drive of the spindle motor is also provided, and this IC is realized by a bipolar IC in which a large number of bipolar transistors are integrated.

By the way, the specifications of the FDD differ depending on the customer. For example, as specifications, DriveSelect 0 or 1, presence or absence of special seek function, presence or absence of auto-chucking function, difference in logic of Density Out signal, difference in logic of mode Select signal, 1M mode 250kbps or 300kbps
Etc. 1 chip I to meet this specification
When C is developed for each specification, various 1-chip I
You have to prepare C. In order to avoid this, a 1-chip IC with a function selection circuit, which already contains all the functions that satisfy all the specifications in advance and selects the functions according to the specifications, is already available. Proposed (for example, Japanese Patent Laid-Open No. 9-978)
39).

On the other hand, as is well known, the FD driven by the FDD includes a disk-shaped magnetic recording medium accessed by a magnetic head, and data is radially arranged on the surface of the magnetic recording medium. A plurality of tracks as a passage for recording are formed concentrically. The number of tracks of the FD is 80 on one side, from the outermost track TR ₀₀ to the innermost track TR ₇₉ . Here, the outermost track TR ₀₀ will be called the outermost track.

When accessing the FD with the magnetic head of the FDD, it is necessary to position the magnetic head at a desired track position. For this purpose, the carriage assembly supporting the magnetic head at its tip may be positioned. Since the stepping motor is adopted as the drive means of the carriage assembly, the FDD can easily position the carriage assembly. Nevertheless, in the FDD, it is necessary to detect only the position of the outermost track TR ₀₀ of the magnetic recording medium of the FD inserted in the FDD. In order to detect the position of the outermost track TR ₀₀ , the carriage assembly is provided with a blocking plate protruding downward from the bottom of the carriage assembly, and the photo interrupter is attached to the substrate adjacent to the main frame facing the carriage assembly. (See, for example, Japanese Patent Laid-Open No. 9-91859). That is, it is possible to detect that the magnetic head is at the position of the outermost track TR ₀₀ of the magnetic recording medium of the FD by blocking the optical path of the photo interrupter by the blocking plate. Such a track position detection mechanism is
It is called "00 sensor" in this technical field.

In a flexible disk drive in which a DD (direct drive) motor such as a spindle motor is used to drive a flexible disk to rotate, an index signal is generated based on the operation of the outer periphery of the DD motor. Specifically, a single-pole magnetized magnet (for example, only the N pole is exposed to the outside) is arranged on the outer peripheral side surface of the disk-shaped casing that constitutes the rotor. Such a magnet is called an index detecting magnet. Further, a printed wiring board on which a predetermined circuit is formed is arranged on the main frame on which the stator of the DD motor is provided. A hall element is provided at a predetermined position of the printed wiring board, which corresponds to the outside of the rotor. This Hall element is called an index detecting Hall element.

As is well known, the "Hall element" is a semiconductor element to which the "Hall effect" is applied. The "Hall effect" means that when a current flows in the conductor in the x direction, a magnetic field is applied in the z direction that is perpendicular to the direction in which the current flows (the x direction). This is a phenomenon in which an electromotive force is generated in the y direction which is orthogonal to both the direction (z direction). The voltage generated at that time is called a Hall voltage.

This Hall element is used not only as a Hall element for detecting an index but also as a rotor position detection for a spindle motor. Such a Hall element is called a position detection Hall element. A spindle motor using such a hall element for position detection is also called a "hall motor".

Such a hall motor requires three hall elements for position detection. In order to omit these position detecting Hall elements, the applicant of the present invention, based on the polarity of the electromotive force induced in the coil in the high impedance state, of the three-phase coils constituting the stator, It has been proposed to switch the state (see, for example, Japanese Patent Laid-Open No. 2000-245125).

Further, as described above, in the conventional case,
A single pole magnetized magnet was used as the index detecting magnet, but it was difficult to obtain a stable index signal generation timing. Therefore, in order to obtain a stable index signal generation timing, the applicant uses a magnet having two poles (that is, an S pole and an N pole arranged side by side) as the index detection magnet. It has already been proposed to do so (Japanese Patent Application Laid-Open No. 200-2000)
No. 1-190055).

In the conventional flexible disk drive, in addition to the main frame, a motor frame for mounting a spindle motor for rotating the medium was also provided. This is because it is necessary to form a frequency generation pattern on the printed wiring board in order to detect the rotation speed of the spindle motor, and this printed wiring board needs to be mounted on the motor frame. for that reason,
The conventional flexible disk drive has a problem that the number of parts is increased and the number of assembling steps is also increased. In order to solve this problem, the present applicant has already proposed a method of controlling the rotation speed of a spindle motor without using a frequency generation pattern (Japanese Patent Laid-Open No. 2001-18818).
In addition to this, a flexible disk drive in which a motor frame portion on which a spindle motor is mounted is integrally formed with a main frame in one piece has already been proposed (see JP 2001-184774 A).

Next, a 3.5-inch flexible disk drive having the above-mentioned frame structure will be described with reference to FIGS. 1 and 2. 1 is an exploded perspective view, and FIG. 2 is a perspective view seen from the front side.

The illustrated flexible disk drive is
This is a device for driving a 3.5-inch flexible disk (described later). The inserted flexible disk is inserted into the flexible disk drive from the direction shown by arrow A in FIGS. 1 and 2. The inserted flexible disk is held on the disk table 11 with its rotating shaft 11a and the center axis of the flexible disk aligned. As will be described later, the disc table 11 is rotatably supported on the surface of the main frame 13. Therefore, the axial direction B of the rotary shaft 11 a of the disc table 11 is parallel to the thickness direction of the main frame 13. The disk table 11 is rotationally driven by a spindle motor (DD motor) 300 provided in a recess of the main frame 13 as described later, and the magnetic recording medium of the flexible disk is thereby rotated. A printed wiring board (not shown) on which a large number of electronic components are mounted is attached to the back surface of the main frame 13.

The flexible disk drive is provided with a pair of upper and lower magnetic heads 14 (only the upper magnetic head is shown) for reading / writing data from / to the flexible disk magnetic recording medium. The magnetic head 14 is supported at its tip by a carriage assembly 15 provided on the back side of the flexible disk drive. That is, the carriage assembly 15 includes an upper carriage 15U that supports the upper magnetic head 14 and a lower carriage 15L that supports the lower magnetic head. The carriage assembly 15 includes the main frame 13
As will be described later, the magnetic head 14 is disposed on the surface of the magnetic head 14 at a distance from the main frame 13 in a predetermined radial direction (direction indicated by an arrow C in FIGS. 1 and 2) with respect to the flexible disk. It is supported so that it can move along.

A stepping motor 16 is fixed to the side wall 131 on the back side of the main frame 13. The stepping motor 16 is the carriage assembly 1
5 is linearly driven along a predetermined radial direction C. More specifically, the stepping motor 16 has a rotary shaft (drive shaft) 161 extending parallel to a predetermined radial direction C,
A male screw is cut on the rotating shaft 161. A tip 161a of the rotary shaft 161 penetrates a hole 132a formed in a bent portion 132 that is erected by cutting and raising from the surface of the main frame 13, and a steel ball 162 is provided. By the hole 132a and the steel ball 162, the rotary shaft 161 is regulated so as to extend parallel to the predetermined radial direction C, and the tip 161a thereof is rotatably held.

On the other hand, the carriage assembly 15 has an arm 151 extending from the lower carriage 15L to the rotary shaft 161, and the tip 151a of this arm 151 engages with the valley portion of the male screw of the rotary shaft 161. . On the other hand, a spring 155 extends from the lower carriage 15L substantially in parallel with the arm 151. That is, the arm 151
The rotation shaft 161 of the stepping motor 16 is sandwiched by the spring 155 and the spring 155.

Therefore, when the rotary shaft 161 of the stepping motor 16 rotates, the tip 151a of the arm 151 is rotated.
Is moved along the portion of the valley of the male screw of the rotating shaft 161,
As a result, the carriage assembly 15 itself moves along the predetermined radial direction C. At any rate, the stepping motor 16 acts as a driving means for moving the carriage assembly 15 linearly along the predetermined radial direction C.

Since the rotary shaft 161 of the stepping motor 16 is provided on one side of the carriage assembly 15, one side of the carriage assembly 15 is movable by the rotary shaft 161 while being separated from the main frame 13. Supported. However, if the carriage assembly 15 is supported only by the rotation shaft 161.
It is not possible to arrange the whole body apart from the surface of the main frame 13. Therefore, by the guide bar 17,
The carriage assembly 15 is guided while being supported on the other side of the carriage assembly 15. The guide bar 17 is provided on the opposite side of the rotation shaft 161 of the stepping motor 16 with the carriage assembly 15 interposed therebetween.
The guide bar 17 extends parallel to the predetermined radial direction C, and has one end 171 and the other end 172 fixed on the surface of the main frame 13 as will be described later. To guide you. As a result, the entire carriage assembly 15 is arranged apart from the surface of the main frame 13.

A flexible printed circuit (FPC) 152 extends from the carriage assembly 15 to the guide bar 17 side.
2 is electrically connected to a main printed wiring board (described later) attached to the back surface of the main frame 13.

The guide bar 17 is held on the surface of the main frame 13 by a guide bar clamp 18.
The guide bar clamp 18 is fixed to the surface of the main frame 13 at its central portion by a binding screw 19. More specifically, the guide bar clamp 18 has a rectangular fixing member 180 that is slightly longer than the guide bar 17, and a hole 180a for allowing the screw shaft 190 of the bind piece screw 19 to pass therethrough is formed substantially at the center of the rectangular fixing member 180. Has been drilled. A pair of arms 181 and 182 for sandwiching one end 171 and the other end 172 of the guide bar 17 extend from one end 180b and the other end 180c of the rectangular fixing member 180, respectively.

Since the guide bar clamp 18 simply holds the guide bar 17 between them, the guide bar 17 cannot be fixed to the surface of the main frame 13 only by this. For this reason, a pair of positioning members for regulating the positions of both ends 171 and 172 of the guide bar 17 are required. As the pair of positioning members, a pair of bent portions 201 and 202 formed by cutting and raising a part of the main frame 13 on the front surface side of the main frame 13 is used.

The lower carriage 15L of the carriage assembly 15 connects the carriage assembly 15 to the guide bar 1
It also functions as a support frame that slidably supports along 7. The lower carriage 15L has a protruding portion (not shown) protruding toward the guide bar 17 side, and the guide bar 17 is provided in the protruding portion.
Is slidably fitted.

The flexible disk drive further has an eject plate 21 and a disk holder 22. The main frame 13, the eject plate 21, and the disc holder 22 are formed by subjecting a metal plate to punching, pressing, bending, or the like.

The eject plate 21 is provided on the main frame 13 so as to be slidable in the insertion direction A of the flexible disk and its opposite direction. As will be described later, the eject plate 21 cooperates with the disc holder 22 to hold the flexible disc when the flexible disc drive operates. The eject plate 21 allows the flexible disk to be inserted into the flexible disk drive along the insertion direction A, or the flexible disk can be removed from the flexible disk drive along the direction opposite to the insertion direction A. In order to make it possible, the flexible disk is held so that it can slide along the insertion direction A. The eject plate 21 has a pair of side walls 210 facing each other. A pair of cam portions 211 is formed on each of the side walls 210. In addition, the cutout portion 212 is formed along the side walls 210 on the bottom surface of the eject plate 21.
A substantially U-shaped notch 213 is formed in the center of the bottom surface of the eject plate 21 so as to surround the disc table 11. Further, a pin (described later) is provided on the lower surface of the eject plate 21, and this pin engages with a locking portion of the eject lever described later.

The disc holder 22 is arranged on the eject plate 21. In the disc holder 22,
A main surface 220 and a pair of side walls 221 facing each other at both ends of the main surface 220 are formed. Projecting pieces 222 (only one is shown) are formed on the side walls 221. These protrusions 222 are attached to the main frame 13 through the cutout portion 212 of the eject plate 21.
Is inserted into the hole 133 of the. By inserting the protrusion 222 into the hole 133 of the main frame 13, the position of the disc holder 22 in the insertion direction A with respect to the main frame 13 is determined, and at the same time, the disc holder 2 is inserted.
2 is the axial direction B of the rotary shaft 11a of the disk table 11.
Can be reciprocated along the. Further, a pair of pins 223 is provided on each of the side walls 221. This pin 2
23 is inserted into the cam portion 211 formed on the side wall 210 of the eject plate 21. Disc holder 22
An eject spring 23 is installed between the eject plate 21 and the eject plate 21.

In this embodiment, the disc holder 22 is provided with the projecting piece 222 and the main frame 13 is provided with the hole 133. However, not limited to this, the main frame is provided with the projecting piece, and the disc holder is provided with the hole. May be provided.

Further, the disc holder 22 has a substantially rectangular opening extending in the predetermined radial direction C at a position corresponding to the upper carriage 15U of the carriage assembly 15 in the central portion on the rear side in the insertion direction A thereof. 224 is provided. Around the opening 224, the periphery of the opening 224 rises upward from the main surface 220 of the disc holder 22.
A substantially U-shaped raised edge 225 is formed. On the other hand, the carriage unassembly 15 includes a pair of lateral arms 153 that extend laterally, and the lateral arms 153 are located on the raised edge 225. As will be described later, when the flexible disk is ejected from the disk holder 22, the side arm 153 engages the raised edge 225, whereby the pair of upper and lower magnetic heads 14 are separated from each other. Furthermore, the disc holder 2
2 also has an opening 226 shaped to allow rotation of the lever portion of the eject lever described later from the right side of the opening 224 on the far side in the insertion direction A.

An eject lever 24 is rotatably provided on the main frame 13 near the carriage assembly 15. More specifically, the main frame 13 has a rod-shaped pin 13 extending upward from its surface.
4 are erected. The eject lever 24 includes a tubular portion 240 into which the rod-shaped pin 134 is fitted, and an arm portion (lever portion) 24 extending from the tubular portion 240 in the radial direction.
1, a protruding portion 242 provided at the free end of the arm portion 241 and extending upward, and an arcuate locking portion 243 extending in the circumferential direction from the free end side of the arm portion 241. An eject lever spring 25 is attached to the eject lever 24 around the tubular portion 240, and the eject lever spring 25 urges the eject lever 24 counterclockwise in the drawing. Projection 24 of eject lever 24
2 is loosely fitted in the opening 226 of the disc holder 22. The projection 242 engages with the right upper edge of the shutter of the flexible disk described later to control opening / closing of the shutter. As shown in FIG. 2, the screw 26 is screwed into the tip of the rod-shaped pin 134, thereby preventing the eject lever 24 from coming off the rod-shaped pin 134.

At the front end of the main frame 13,
A front panel 27 is attached. The front panel 27 includes an opening 271 for inserting and removing the flexible disk, and a door 272 for opening and closing the opening 271. An eject button 28 is provided on the front panel 27 so as to be movable in the front-rear direction. The eject button 28 is fitted into the protrusion 214 protruding forward at the front end of the eject plate 21.

A flexible disk (FD) driven by the flexible disk drive (FDD) shown in FIGS. 1 and 2 will be described with reference to FIG. The illustrated flexible disk 40 includes a disk-shaped magnetic recording medium 41 and a shell 4 that covers the magnetic recording medium 41.
2 and a shutter 43 that can slide in the direction of arrow D. The shutter 43 has a window 43a. The shutter 43 is biased by a spring member (not shown) in the direction opposite to the arrow D direction. The shell 42 has an opening 42a that allows the magnetic recording medium 41 to be accessed by the magnetic head 14 of the flexible disk drive.
The opening 42a is covered with a shutter 43 as shown in FIG. 3 when the flexible disk 40 is not inserted into the flexible disk drive.
When the flexible disk 40 is inserted into the flexible disk drive, the upper right edge 4 of the shutter 43
The protrusion 242 of the eject lever 24 is engaged with 3b to slide the shutter 43 in the direction of arrow D.

The shell 42 has a chamfered portion 42b at the upper right corner for preventing reverse insertion (inserted with the front and back sides and the insertion direction reversed).
Are formed. Further, the shell 42 is provided with a write protection hole 44 at the left side corner portion at the rear end in the insertion direction A thereof.

As described above, in the flexible disk 40 driven by the flexible disk drive, on the surface of the magnetic recording medium 41 accessed by the magnetic head 14, a plurality of tracks are provided as a passage for recording data. (Not shown) is concentrically formed along the radial direction. The number of tracks of the flexible disk 40 is 80 on one side, and ranges from the outermost track (the outermost track) TR ₀₀ to the innermost track TR ₇₉ .

A track position detecting mechanism (00 sensor) for detecting the position of the endmost track TR ₀₀ of the magnetic recording medium 41 will be described with reference to FIG. 4 in addition to FIG. 1.

In the carriage assembly 15, the lower carriage 15L is provided with a blocking plate 154 protruding downward from its bottom. On the other hand, a main printed wiring board 30 is arranged on the lower surface side of the main frame 13 facing the carriage assembly 15, and a photo used as a track position detection mechanism (00 sensor) is arranged on the main printed wiring board 30. Interrupter 3
1 is implemented. Therefore, the main frame 13 is provided with a hole 13b for passing the photo interrupter 31.

As is well known, the photo interrupter 31
Is a first protrusion 3 including a light emitting element (not shown).
1-1, and the 2nd protrusion part 31-2 in which the light receiving element (not shown) was incorporated. First protrusion 31-1 and second
The protruding portions 31-2 are arranged so as to face each other as shown in the drawing, and an opening (not shown) is provided on each of the facing wall surfaces. Through these two openings,
An optical path from the light emitting element to the light receiving element is formed. Then, the blocking plate 154 has the first protrusion 3 as shown in the drawing.
It passes through the passage between 1-1 and the second protrusion 31-2.

In the 00 sensor having such a configuration, the magnetic head 14 blocks the optical disk of the flexible disk 4 by blocking the optical path of the photo interrupter 31 by the blocking plate 154.
It is possible to detect that it is at the position of the endmost track TR ₀₀ of the magnetic recording medium 41 of 0.

Next, a DD motor (spindle motor) used in the flexible disk drive will be described with reference to FIG.

The illustrated DD motor 300 includes a rotor 310.
And a stator 320 combined with this rotor 310
It consists of and. The rotor 310 has a substantially trapezoidal section 312 in a central portion of a disk-shaped metal casing 311 which projects upward. The disc table 11 is fixed to the upper surface of the substantially trapezoidal section 312.

A rotor shaft 11a made of metal is integrally fixed to the center of the rotor 310 so as to penetrate the casing 311 and the disk table 11. That is, the casing 311 and the rotary shaft 11a are integrally assembled when the disk table 11 is injection-molded with a plastic magnet. Casing 311
Has a tubular body 314 extending downward at the periphery thereof, and a ring-shaped permanent magnet 315 is attached to the inside of the tubular body 314.

The permanent magnet 315 is main magnetized in the circumferential direction. The main magnetization is also called a drive magnetizing part.

Further, as shown in FIG.
Magnets 340 for index detection at predetermined positions on the outer peripheral wall
Is attached.

An arm 316 is attached to the lower surface side of the substantially trapezoidal section 312, and a drive rotor 317 is rotatably provided on the arm 316. The substantially trapezoidal section 312 and the disc table 11 are provided with substantially rectangular holes (not shown), and the drive rollers 317 are arranged so as to project above the disc table 11 through these holes. The flexible disk 40 (FIG. 3) housed in the flexible disk drive is
The magnetic recording medium 41 (FIG. 3) is rotatably driven by being mounted on the disc table 11 and fitting the drive roller 317 into the hole formed in the hub (not shown) of the flexible disc 40.

On the other hand, the stator 320 is attached to the motor frame portion 13-2 of the main frame 13 as described later. The stator 320 includes a core assembly having a plurality of radially extending stator cores 321 and a stator coil 3 wound around each of the plurality of stator cores 321.
22 and a center metal (bearing portion) 323 for receiving the rotating shaft 11a.

The frame structure (main frame) 13 used in the flexible disk drive shown in FIGS. 1 and 2 will be described with reference to FIG.
FIG. 6 is a perspective view of the main frame (frame structure) 13 as viewed from diagonally below.

As is apparent from FIG. 6, the illustrated main frame (frame structure) 13 has a main frame portion 13-1 into which the flexible disk 40 (FIG. 3) is inserted.
And a motor frame portion 13-on which is mounted a spindle motor 300 (which will be described later in detail with reference to the drawings) for rotationally driving the inserted flexible disk 40.
1 and 1 are integrated into one piece. That is, the main frame 13 also serves as a motor frame.

Here, the motor frame portion 13-2 is
It has a narrowed shape for drawing. This is the motor frame portion 13-2 when viewed from the back surface (bottom surface) side.
Is a structure protruding to the back surface (bottom surface) side. In the motor frame portion 13-2, an opening 13-2a for drawing out the lead wire of the spindle motor 300 is formed in a portion which becomes a top surface when viewed from the back surface (bottom surface) side.

The motor frame portion 1 shown in FIG.
The narrowed shape of 3-2 is circular, but is not limited to this, and may be polygonal or elliptical depending on the depth and the material. Further, the shape of the narrowed shape of the frame portion 13-2 is not limited to that shown in the drawing, and may be various shapes. Further, the motor frame portion 13
-2 and the main frame 13-1 are of course not limited to the illustrated connection.

The illustrated flexible disk drive is
By deleting the frequency generation pattern necessary for controlling the drive of the spindle motor 300, that is, by deleting the printed wiring board for forming it, it is possible to adopt the main frame 13 having the above-described shape. I have to. Further, by deleting the frequency generation pattern, magnetizing for motor servo applied to the bottom surface of a permanent magnet (described later) of the rotor of the spindle motor 300 is also unnecessary. Instead, the illustrated flexible disk drive is provided with electronic processing means that performs a function equivalent to that when a frequency generation pattern is used. Since the detailed operation of such an electronic processing means is disclosed in the above-mentioned Japanese Patent Laid-Open No. 2001-178185, its explanation is omitted here.

The main printed wiring board 30 of the illustrated flexible disk drive is attached to the back side of the main frame portion 13-1 of the main frame 13.
As shown in FIG. 6, this main printed circuit board 30
Has a shape that does not overlap the motor frame portion 13-2. The main printed wiring board 30 has its front surface 30a separated from the back surface of the main frame portion 13-1 by a predetermined distance, and its back surface 30b more than the top surface of the motor frame portion 13-2. -1 is cut and raised from the main frame portion 13-1 so as to be close (lower) to the back surface of -1, and is fixed by a screw 33 to a support piece (not shown) having a screw hole formed at its tip.

Referring to FIG. 7 in addition to FIG. 6, on the main surface side of the main frame 13, the motor frame portion 13-2
Of the spindle motor 300 mounted on the stator 320
The leading end (lead wire) of the coil wound around is drawn out to the back side from the opening 13-2a formed in the motor frame portion 13-2, and is connected and fixed to a predetermined terminal of the main printed wiring board 30. It Normally, the lead wires are a total of four lead wires, that is, three lead wires that are one end of the U-phase coil, the V-phase coil, and the W-phase coil, and a lead wire that bundles the other ends of these coils into one. Including. The illustrated flexible disk drive includes a sub-printed wiring board 50 that guides these lead wires 60 and has an index detecting hall element 55 mounted thereon.

Here, the main printed wiring board 30 is
The spindle motor 300 extends in a direction orthogonal to the rotation axis 11a. On the other hand, the sub printed wiring board 50 is located at a position close to the outer peripheral side surface of the rotor 310 of the spindle motor 300 so as to extend in the direction parallel to the rotation shaft 11a of the spindle motor 300. Is attached to.

Then, the hall element 5 for index detection
5 is attached to the sub-printed wiring board 50 so that its magnetic field detection surface faces the outer peripheral side surface of the rotor 310. In addition, the index detection Hall element 55 is
It has four terminals (not shown), and these four terminals are electrically connected to the wiring (not shown) on the main printed wiring board 30 via the solder 97. Note that these solders 57 not only perform such electrical connection but also serve to mechanically bond the main printed wiring board 30 and the sub printed wiring board 50.

The lead wire 60 drawn out from the opening 13-2a is hooked in the groove 56 of the sub printed wiring board 50, and its tip is connected and fixed to a predetermined terminal 35 of the main printed wiring board 30. It This is shown in FIG.

Next, the frame structure of the conventional flexible disk drive described above will be described with reference to FIGS. FIG. 8 is a perspective view of a main frame 13 used in a conventional flexible disk drive. FIG. 9 is a perspective view of a lower cover (lower lid) 70 that covers the lower surface (bottom surface) of the main frame 13 shown in FIG. FIG. 10 shows the main frame 13 shown in FIG. 8 and FIG.
It is a perspective view of the state where it combined with the lower cover 70 illustrated in FIG.

In the conventional flexible disk drive, the medium 40 (FIG. 3) and the carriage assembly 1 are used.
5. Due to the space of the I / F connector and the like, the size of the main frame 13 is limited to some extent. That is, the carriage assembly 15, the stepping motor 16, the spindle motor 300, the eject mechanism portion, the printed wiring board, the external component mounting structure, and the like are all mounted (mounted) on the conventional main frame 13.
Therefore, the shape (size) of the main frame 13 serving as a base needs to be a size that covers the entire surface of the flexible disk drive product. For example, the size (dimension) of the conventional main frame 13 is about 1 × length × width × height.
It is 50 mm × 100 mm × 20 mm. The plate thickness of the main frame 13 is 1 mm.

In order to reduce the cost (perform VE) at the design stage, the material development is reduced to reduce the material cost. However, in this case, the main frame 13 could not be made small due to the space problem of the above components. Further, the medium 40 is received by the shape of the main frame 13 after the medium chucking. Therefore, the main frame 13 is limited to a certain size.

The conventional lower cover 70 has only the function of covering the lower surface of the main frame 13.

As shown in FIG. 11, the main frame 13 has four convex portions 135 in order to slidably install the eject plate 21 thereon. Therefore, the eject plate 21 does not bend or deform due to impact or the like.

Further, as shown in FIG. 12, the main frame 13 includes all slide structure guides of the eject mechanism. In other words, the main frame 13 has slide guides 136 having a structure that matches the shape of the eject plate 21 that slides at four locations.

[0063]

As described above, in the conventional flexible disk drive, there is a problem that the size of the main frame 13 is limited because all the parts are mounted.

Therefore, an object of the present invention is to provide a flexible disk drive capable of reducing the material cost.

Another object of the present invention is to provide a flexible disk drive which can reduce the cost of the product (make it VE).

Still another object of the present invention is to provide a flexible disk drive capable of reducing the weight of the product (making the weight lighter).

[0067]

According to the first aspect of the present invention, the main frame (13A) into which the flexible disk (40) is inserted and the lower cover (70A) covering the lower surface of the main frame are provided. In the flexible disk drive, the mainframe (13A) is
A carriage assembly (15) for holding the magnetic head (14), a stepping motor (16) for sliding the carriage assembly along a predetermined radial direction (C), and rotationally driving the inserted flexible disk. And a lower cover (70) having a size for mounting only a portion corresponding to substantially half of the spindle motor (300) for
A) has a function as a subframe having a function corresponding to the front part of the deleted frame, and is configured to function as one frame by combining the mainframe and the lower cover subframe. A flexible disk drive characterized by

In the above flexible disk drive, it is preferable that the lower cover has the slide guide structure portions (704, 705) of the eject mechanism as a sub-frame.

The flexible disk drive further has an eject plate (21A) slidably held on the main frame as one of the eject mechanisms. The lower cover (70A) has a main surface (700) and a pair of side walls (70) facing each other at both ends of the main surface.
1) and. The main surface preferably has a raised portion (702) raised above the front surface portion. Further, the eject plate preferably has a protrusion (215) protruding downward at its front end. In this case, this protrusion is arranged on the raised portion with a slight gap. Further, the pair of side walls of the lower cover has a pair of side stoppers (70
It is desirable to have 3).

The flexible disk drive further has an eject plate (21A) slidably held on the main frame as one of the eject mechanisms. The lower cover (70A) has a main surface (700) and a pair of side walls (70) facing each other at both ends of the main surface.
1) and. The main surface has a raised portion (704) raised upward on the front surface thereof, and the raised portion has an L-shaped opening (704) extending in the insertion direction (A).
You may have a). In this case, the eject plate is
It has a protrusion (216) projecting downward at its front end, and this protrusion has a shoulder (216a) that abuts on the raised portion and L
L-shaped hook part (216b) to be inserted into the letter-shaped opening
Good to have. As a result, one slide guide structure portion is formed by the combination of the raised portion and the protrusion.

The flexible disk drive further has an eject plate (21A) slidably held on the main frame as one of the eject mechanisms. The eject plate may have an L-shaped opening (271a) extending in the insertion direction (A) on the front surface portion of the bottom surface thereof. In this case, the lower cover (70A) has the main surface (7A).
00) and a pair of side walls (701) facing each other at both ends of the main surface, and the main surface has a bent portion (70 formed by cutting and raising so as to project upward at the front surface portion thereof.
5), the bend may have a shoulder (705a) abutting the lower surface of the eject plate and an L-shaped hook portion (705b) inserted into the L-shaped opening. As a result, one slide guide structure portion is formed by the combination of the L-shaped opening and the bent portion.

According to the second aspect of the present invention, the main frame (13A) for the flexible disk drive for driving the inserted flexible disk (40).
The main frame is a high precision component (15, 1
A mainframe is obtained which is characterized in that it has dimensions to mount only 6,300).

The main frame (13A) is a high precision component, for example, a carriage assembly (15) holding a magnetic head (14) and the carriage assembly is slid in a predetermined radial direction (C). Stepping motor (16) and a spindle motor (3) for rotationally driving the inserted flexible disk.
(00) and only a portion corresponding to substantially half of (00).

According to the third aspect of the present invention, there is provided a frame structure for a flexible disk drive for driving the inserted flexible disk (40), which comprises only high precision parts (15, 16, 300). A main frame (13A) having a size to be mounted and having a structure in which the front surface of the frame is removed, and a lower cover for covering the lower surface of the main frame, which is a low precision component (702) corresponding to the front surface of the deleted frame. , 703, 704, 70
5) A frame structure characterized by having a lower cover (70A) having a function as a sub-frame for mounting the main frame and a combination of the sub-frame of the lower cover so as to perform the function as one frame. Is obtained.

In the frame structure, the main frame (13A) is a high precision component, for example, a carriage assembly (15) for holding the magnetic head (14).
And move this carriage assembly in the specified radial direction (C)
Motors for sliding along (16)
And a portion corresponding to substantially half of the spindle motor (300) for rotationally driving the inserted flexible disk. And the lower cover (70
A) may have a slide guide structure portion (704, 705) of the eject mechanism as a low precision component.

It should be noted that the reference numerals in the above parentheses are given for facilitating understanding and are merely examples, and it goes without saying that they are not limited to these.

[0077]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

A frame structure for a flexible disk drive according to an embodiment of the present invention will be described with reference to FIGS. 13 to 15. FIG. 13 is a perspective view of a main frame 13A used in the flexible disk drive according to this embodiment. FIG. 14 is a perspective view of a lower cover (lower lid) 70A that covers the lower surface (bottom surface) of the main frame 13A shown in FIG. FIG. 15 is a perspective view showing a state in which the main frame 13A shown in FIG. 13 and the lower cover 70A shown in FIG. 14 are combined.

As is clear from FIG. 13, the illustrated main frame 13A has a carriage assembly 15 (FIG. 1) for holding the magnetic head 14 (FIG. 1) and the carriage assembly 15 along a predetermined radial direction C. A stepping motor 16 (FIG. 1) for sliding and a portion corresponding to substantially half of a spindle motor 300 (FIG. 5) for rotationally driving the inserted flexible disk 40 (FIG. 3) are mounted. Has a size that That is, the main frame 13A has a structure in which the front surface of the frame is removed.

Here, the carriage assembly 15, the stepping motor 16, the spindle motor 300 and the like are required to have relatively high precision in order to exert their functions (maintain characteristics) among the components constituting the flexible disk drive. Parts (hereinafter referred to as “high-precision parts”). In the present embodiment, such a high precision component is mounted on the main frame 13A.

As described above, in the main frame 13A, since the structure of the front surface portion of the frame (the portion on the front panel 27 side from the central portion of the motor frame portion 13-2A) is deleted, the development of the material is reduced, Material costs can be reduced. The size (size) of the illustrated main frame 13A is about 80 m in length (length) × width × height.
It is m × 100 mm × 10 mm. That is, compared to the conventional main frame 13 (FIG. 8), the main frame 13A (FIG. 13) according to the present embodiment has a size (dimension) of about 1/2 in the length direction and the height direction. Become. Also,
The material cost can be reduced by lowering the height of both sides of the main frame 13A and making the plate thickness 0.8 mm from the conventional 1 mm.

Since the structure of the front surface portion of the main frame 13A is deleted, it is necessary to supplement this portion by some form (means). Therefore, in the present invention, as will be described later, the lower cover 70A is made to have a function as a sub-frame having a function corresponding to the front surface portion of the deleted frame. The function corresponding to the front surface of the deleted frame includes a slide guide structure portion of the eject mechanism. The slide guide structure part of this eject mechanism exhibits its function (maintains the characteristics) among the components that make up the flexible disk drive.
This is a component that may be relatively low in accuracy (hereinafter, referred to as "low precision component").

Referring to FIGS. 16 and 17, eject plate 21A is slidably held on main frame 13A. As mentioned above, the mainframe 13
Since A does not have the structure of the front surface of the frame, if the eject plate 21A is simply installed on the main frame 13A, the eject plate 21A due to a shock or the like will be damaged.
It is not possible to prevent the occurrence of bending or deformation. Therefore, in the present invention, as described below, the lower cover 70A and the eject plate 21A which serve as the sub-frame are provided with a device for preventing the eject plate 21A from being deformed to cause a defective eject operation.

More specifically, the lower cover 70A has a main surface 700 and a pair of side walls 701 facing each other at both ends of the main surface. The main surface 700 has a first raised portion 702 that is raised upward on the front surface thereof.
On the other hand, the eject plate 21A has a first protrusion 215 protruding downward at its front end. This first protrusion 21
As shown in FIG. 18, 5 is arranged on the first raised portion 702 of the lower cover 70A with a slight gap. In other words, during the sliding of the eject plate 21A, the first protrusion 215 has the first protrusion 702.
It will move with a gap above. On the other hand, the pair of side walls 701 of the lower cover 70A has a pair of side stoppers 703 formed by cutting and raising them inward.
As shown in FIG. 19, the eject lever 21A slides on the pair of side stoppers 703.

As described above, since the lower cover 70A is provided with the first raised portion 702 and the pair of side stoppers 703 and the eject plate 21A is provided with the first projection 215, the eject plate 21 caused by an impact or the like is generated.
Bending and deformation of A can be prevented.

Next, in addition to FIG. 16 and FIG.
21 and FIG. 21, the slide guide structure portion of the eject mechanism according to the present embodiment will be described.

As described above, since the main frame 13A does not have the structure of the front surface of the frame, the slide guides 136 can be provided at only two positions on the main frame 13. Therefore, it is necessary to provide the slide guide structure portion of the eject mechanism at two insufficient places.

As shown in FIG. 16, the lower cover 70
The main surface 700 of A has a second raised portion 704 that is raised upward in the center slightly to the left of the front surface portion. This second raised portion 704 is L extending in the insertion direction A.
It has a character-shaped opening 704a. On the other hand, as shown in FIG. 17, the eject plate 21A has a second protrusion 216 protruding downward at its front end. This second protrusion 21
As shown in FIG. 20, 6 is a shoulder 216a that abuts the second raised portion 704 of the lower cover 70A and an L-shaped hook portion 216 that is inserted into the L-shaped opening 704a.
with b. That is, one slide guide structure portion is formed by the combination of the second raised portion 704 and the second protrusion 216.

As shown in FIG. 17, the eject plate 21A has an L-shaped opening 217a extending in the insertion direction A on the right front surface of the bottom surface thereof. On the other hand, FIG.
6, the main surface 700 of the lower cover 70A is shown.
Has a bent portion 705 formed by cutting and raising so as to project upward at the right front surface portion thereof. This bent portion 705
As shown in FIG. 21, the eject plate 2
Shoulder 705a that abuts the lower surface of 1A, and L-shaped opening 21
7a and an L-shaped hook portion 705b to be inserted.
That is, the L-shaped opening 2 of the eject plate 21A
The combination of 17a and the bent portion 705 constitutes another slide guide structure portion.

As described above, in the present embodiment, the combination of the main frame 13A and the sub-frame of the lower cover 70A functions as one frame.

The present invention is not limited to the above embodiment,
Of course, various changes and modifications can be made without departing from the spirit of the present invention. For example, the slide guide structure is composed of a combination of holes and bends formed on the eject plate and the lower cover, so it is possible to freely form a hole on one side and a bend on the other. can do.

[0092]

As is apparent from the above description, according to the present invention, the main frame has a size for mounting only high-precision parts and has a structure in which the front portion of the frame is removed. The lower cover that covers the lower surface of the frame has a function as a subframe that mounts low-precision parts corresponding to the front surface of the deleted frame, and functions as a single frame by combining the mainframe and the lower cover subframe. Because I tried to fulfill
The material cost can be reduced, the product cost can be reduced (VE conversion), and the product weight can be reduced.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing a main part of a conventional flexible disk drive.

FIG. 2 is a schematic perspective view of the flexible disk drive shown in FIG. 1 as seen obliquely from the front.

FIG. 3 is a plan view showing a flexible disk driven by a flexible disk drive.

FIG. 4 is a cross-sectional view illustrating an installation structure of a track position detection mechanism (00 sensor) used in a flexible disk drive.

5 is a cross-sectional view showing a configuration of a DD motor (spindle motor) used in the flexible disk drive shown in FIG.

6 is a perspective view of a main frame used in the flexible disk drive shown in FIG. 1 in which a main printed wiring board and a sub printed wiring board are attached, as viewed from a lateral lower side.

7 is a diagram showing a state in which a lead wire is hooked in a groove of the sub printed wiring board shown in FIG.

8 is a perspective view of a main frame used in the flexible disk drive shown in FIG. 1. FIG.

9 is a bottom surface (bottom surface) of the main frame shown in FIG.
It is a perspective view of a lower cover (lower lid) that covers the.

10 is a perspective view showing a state in which the main frame shown in FIG. 8 and the lower cover shown in FIG. 9 are combined.

11 is a perspective view of the main frame shown in FIG. 8 as seen from diagonally above and above.

12 is a perspective view of the main frame shown in FIG. 8 as viewed from diagonally above and above.

FIG. 13 is a perspective view of a main frame used in the flexible disk drive according to the embodiment of the present invention.

14 is a perspective view of a lower cover (lower lid) that covers a lower surface (bottom surface) of the main frame illustrated in FIG.

15 is a perspective view showing a state in which the main frame shown in FIG. 13 and the lower cover shown in FIG. 14 are combined.

16 is a perspective view of a state in which a spindle motor and the like are further assembled in the state of FIG. 15 as seen obliquely from above and above.

FIG. 17 is a perspective view of the eject plate slidably held on the main frame shown in FIG. 13 as seen obliquely from above and above.

18 is a perspective view showing a main part of the lower cover shown in FIG. 14 in which the eject plate shown in FIG. 17 is assembled.

19 is a perspective view showing a main part of a state in which the eject plate shown in FIG. 17 is further assembled in the state of FIG.

20 is a perspective view showing a main part of a state in which the eject plate shown in FIG. 17 is further assembled in the state of FIG.

21 is a perspective view showing a main part of a state in which the eject plate shown in FIG. 17 is further assembled in the state of FIG.

[Explanation of symbols]

13A mainframe 14 magnetic head 15 Carriage assembly 16 stepping motor 21A eject plate 215 Protrusion 216 Protrusion 216a shoulder 216b L-shaped hook 40 flexible disk 70A lower cover 700 main surface 701 side wall 702 bulge 703 Side stopper 704 bulge 704a L-shaped opening 705 Bend 705a shoulder 705b L-shaped hook 300 spindle motor

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Makoto Takahashi             5 Tategawa 1-1059, Yamagata City, Yamagata Prefecture             Yamagata Mitsumi Co., Ltd. (72) Inventor Noriyuki Kobayashi             5 Tategawa 1-1059, Yamagata City, Yamagata Prefecture             Yamagata Mitsumi Co., Ltd. F term (reference) 5D046 BA14 CA02 CD01 CD05 HA10

Claims (10)

[Claims] 1. A flexible disk drive having a main frame into which a flexible disk is inserted and a lower cover for covering a lower surface of the main frame, wherein the main frame includes a carriage assembly for holding a magnetic head, and the carriage assembly. And a stepping motor for sliding along a predetermined radial direction,
The lower cover has a structure in which only the portion corresponding to substantially half of the spindle motor for rotationally driving the inserted flexible disk is mounted, and the front surface of the frame is deleted. It has a function as a sub-frame having a function corresponding to the front surface of the deleted frame, and is configured to fulfill a function as one frame by a combination of the main frame and the sub-frame of the lower cover. Flexible disk drive characterized by. 2. The flexible disk drive according to claim 1, wherein the lower cover has a slide guide structure portion of an eject mechanism as the subframe. 3. The eject mechanism, as one of the eject mechanisms, further includes an eject plate slidably held on the main frame, wherein the lower covers are opposed to each other at a main surface and at both ends of the main surface. A pair of side walls, the main surface has a raised portion that rises upward on the front surface thereof, the eject plate has a protrusion protruding downward at its front end, and the protrusion has a slight gap. The flexible disk drive according to claim 2, wherein the flexible disk drive is disposed on the raised portion. 4. The flexible disk drive according to claim 3, wherein the pair of side walls of the lower cover have a pair of side stoppers formed by cutting and raising the side walls inward. 5. The eject mechanism, as one of the eject mechanisms, further includes an eject plate slidably held on the main frame, wherein the lower covers are opposed to each other at a main surface and at both ends of the main surface. And a pair of side walls, the main surface has a raised portion that rises upward on the front surface thereof, the raised portion has an L-shaped opening extending in the insertion direction, and the eject plate has The front end has a protrusion protruding downward, and the protrusion has a shoulder that abuts the raised portion and an L-shaped hook portion that is inserted into the L-shaped opening, and a combination of the raised portion and the protrusion. The flexible disk drive according to claim 2, wherein one slide guide structure portion is constituted by the above. 6. The eject mechanism further includes an eject plate slidably held on the main frame, as one of the eject mechanisms, and the eject plate has an L-shape extending in an insertion direction on a front surface portion of a bottom surface thereof. The lower cover has a V-shaped opening, and the lower cover has a main surface and a pair of side walls facing each other at both ends of the main surface, and the main surface is cut and raised so as to project upward at a front surface portion thereof. A bent portion formed, the bent portion having a shoulder that abuts a lower surface of the eject plate, and an L-shaped hook portion that is inserted into the L-shaped opening, and the L-shaped opening and the bending portion. 3. One slide guide structure part is constituted by a combination with a part.
Flexible disk drive described in. 7. A main frame for a flexible disk drive for driving an inserted flexible disk, wherein the main frame is sized to mount only high-precision components. 8. The main frame, as the high-precision component, a carriage assembly holding a magnetic head, a stepping motor for sliding the carriage assembly in a predetermined radial direction, and the inserted flexible body. 8. The main frame according to claim 7, which is mounted with only a portion corresponding to substantially half of a spindle motor for rotationally driving a disk. 9. A main frame having a frame structure for a flexible disk drive for driving an inserted flexible disk, the frame having a size for mounting only high-precision components, and having a structure in which a front part of the frame is removed. And a lower cover that covers the lower surface of the main frame, the lower cover having a function as a sub-frame for mounting low-precision components corresponding to the front surface of the deleted frame, the main frame and the lower cover A frame structure characterized by performing a function as one frame by combining with the sub-frame. 10. The main frame, as the high-precision component, a carriage assembly holding a magnetic head, a stepping motor for sliding the carriage assembly along a predetermined radial direction, and the inserted flexible body. 10. Only the part corresponding to substantially half of a spindle motor for rotationally driving a disk is mounted, and the lower cover has a slide guide structure part of an eject mechanism as the low-precision part. Frame structure.